Researchers demonstrated cryogen-free operation of a superconducting radio-frequency cavity that might ease barriers to its use in societal applications.
Scientists improve our understanding of the relationship between fundamental forces by re-creating the earliest moments of the universe.
CMS observes Higgs boson decays into bottom quarks, furthering our knowledge of how the particles that make up matter behave.
New direct evidence for Higgs interactions with top and bottom quarks confirms its role in generating mass for constituents of matter.
Comparing new prediction to measurements of muons’ precession could potentially help scientists discover new subatomic particles.
Scientists are developing better models that describe both neutrino and antineutrino data, which can offer insights into the nature of the universe.
Neutral pion production is a major character in a story of mistaken identity worthy of an Agatha Christie novel.
MicroBooNE neutrino experiment cuts through the noise, clearing the way for signals made by the hard-to-detect particle.
Detector measures the energy a neutrino imparts to protons and neutrons to help explain the nature of matter and the universe.
Researchers demonstrate a new technique that could lead to significantly higher power proton beams used to answer tough scientific questions.
Seeding x-ray free electron lasers with customized electron beams produces incredibly stable laser pulses that could enable new scientific discoveries.
New results confirm the rate of Higgs boson production, matching our understanding of how the universe works.
